Dr. Exley and other aluminum experts such as molecular biologist Dr. Lucija Tomljenovic have confirmed that aluminum readily and actively traverses the blood-brain barrier to selectively accumulate in brain tissues, where it induces unwelcome changes in brain biochemistry.

As Dr. Exley has noted, “There are no ‘normal’ levels of brain aluminum,” meaning that “its presence in brain tissue, at any level, could be construed as abnormal” [emphasis added].

Below is a video of him speaking on his study.

Documenting Aluminum in the ASD Brain

In light of the fact that even minute amounts of aluminum can have adverse neurological consequences, Dr. Exley’s newest paper — which reports on the first-ever study of aluminum in ASD brain tissue — is groundbreaking.

Published in the Journal of Trace Elements in Medicine and Biology, the paper documents some of the highest values for aluminum in human brain tissue ever recorded. Using a two-pronged study design (see box), the researchers measured and characterized aluminum deposits in brain tissues from five to ten ASD donors, most of whom died in their teens or twenties.

Frozen tissue was available from one female donor (age 44) and four male donors (ages 15, 22, 33 and 50) who, when alive, had a confirmed ASD diagnosis. The researchers quantified aluminum levels in 59 tissue samples representing five different areas of the brain (frontal, parietal, occipital, temporal and hippocampal).

Qualitative component: Using a technique called fluorescence microscopy, the researchers visualized aluminum deposits according to their presence (a) insideversus outside the brain cells and (b) in the two types of brain tissue (grey matterversus white matter).

For this component, fixed tissue samples were available for the same five donors plus an additional five donors diagnosed with ASD, including two females (ages 13 and 29) and three males (ages 14, 22 and 29).

What the research team found was startling. The study’s quantitative arm documented “consistently high” aluminum levels representing “some of the highest values for brain aluminum content ever measured in healthy or diseased tissues.” Specifically:

All five individuals had at least one brain tissue with a “pathologically significant” level of aluminum, defined as greater than or equal to 3.00 micrograms per gram of dry brain weight (μg/g dry wt). (Dr. Exley and colleagues developed categories to classify aluminum-related pathology after conducting other brain studies, wherein older adults who died healthy had less than 1 μg/g dry wt of brain aluminum.)

Aluminum levels were particularly high in the male brains, including in a 15-year-old boy with ASD who had the study’s single highest brain aluminum measurement (22.11 μg/g dry wt)—many times higher than the pathologically significant threshold and far greater than levels that might be considered as acceptable even for an aged adult.

Some of the elevated aluminum levels rivaled the very high levels historically reported in victims of dialysis encephalopathy syndrome (a serious iatrogenic disorder resulting from aluminum-containing dialysis solutions).

The study’s qualitative findings were equally concerning:

Across the 10 donors, the investigators identified 150 aluminum deposits. All 10 donors had aluminum deposits in at least one tissue.

Aluminum deposits were markedly more prevalent in males than females (129 deposits in seven males, averaging over 18 deposits each, versus 21 deposits in three females, for an average of 7).

In males, most aluminum deposits were inside cells (80/129), whereas aluminum deposits in females were primarily extracellular (15/21). The majority of intracellular aluminum was inside non-neuronal cells (microglia and astrocytes).

The researchers also identified aluminum-loaded lymphocytes in the meninges (the layers of protective tissue that surround the brain and spinal cord) and in similar inflammatory cells in the vasculature, furnishing evidence of aluminum’s entry into the brain “via immune cells circulating in the blood and lymph” and perhaps explaining how youth with ASD came to acquire such shockingly high levels of brain aluminum.

The Importance of Glial Cells

There are three broad categories of non-neuronal (glial) cells, including astrocytes (which support neuronal signaling), oligodendrocytes (which create myelin) and microglia (responsible for repairing damage). In discussing their results, Dr. Exley’s team comments that the intracellular location of most of the aluminum in these non-neuronal cells was the “standout observation” for ASD.

…environmental factors can alter microglia function, negatively affecting brain development and synaptic connectivity; when this occurs during important developmental periods, there may be ‘consequences throughout life.’

Unlike other brain cells, the microglia (which represent about 10% of brain cells) are dedicated immune cells. Microglia also play a key role in the process known as synaptic pruning that takes place during vital phases of cognitive development in early childhood as well as adolescence, continuing into the late 20s.

This process, which some observers have likened to “neural spring cleaning,” allows the maturing brain to shed “weak or redundant [neuronal] connections.” Given this and other important microglial functions, the microglia have attracted considerable research attention as key players in brain disease, including autism.

(Astrocytes also have implications for autism, given the role of astrocyte dysfunction in seizures — a condition that is frequently comorbid with ASD.)

A pivotal review article published in 2017 observes that “microglia are now known to be active participants in brain function and dysfunction” and notes that “aberrant [synaptic] pruning during critical developmental periods could contribute to neurodevelopmental disorders.”

Evidence suggesting that the microglia are dysfunctional in ASD includes findings from postmortem ASD brain studies showing “altered microglial counts, morphology, and neuronal interaction” as well as altered expression of microglia-specific genes.

It is clear to many researchers that environmental factors can alter microglia function, negatively affecting brain development and synaptic connectivity; when this occurs during important developmental periods, there may be “consequences throughout life.”

The study’s results strongly suggest that aluminum is entering the brain in ASD via cells that have become loaded up with aluminum in the periphery. Where is the aluminum coming from? One of the most pervasive routes of modern-day exposure to neurotoxic aluminum is via aluminum adjuvants in vaccines.

Elsewhere, Dr. Exley has described the “migratory capabilities” of aluminum-based adjuvants “at sites distant to the injection site,” including the brain.

The extreme levels of aluminum found in the brains of the study’s teenage donors have alarming implications for the entire generation of highly aluminum-vaccinated children.

In the ASD brain paper, Dr. Exley and coauthors point out that the “burgeoning” use of aluminum-adjuvant-containing childhood vaccines “has been directly correlated with increasing prevalence of ASD.”

A 2011 study by Lucija Tomljenovic and Christopher Shaw confirms that aluminum-containing vaccines are having crippling neurological consequences.

Their analysis shows that children from countries where ASD prevalence is highest have the highest exposure to aluminum from vaccines; moreover, children’s increased exposure to aluminum adjuvants over the two decades starting in the 1990s significantly correlates with the increase in ASD prevalence in the U.S. Counting the shots now pushed during pregnancy, highly vaccinated American children may receive up to 73 total vaccine doses by age 18, including multiple rounds of injected aluminum.

Crucially, Dr. Exley and coauthors note that what “discriminates [their] data from other analyses of brain aluminum in other diseases is the age of the ASD donors” [emphasis added].

The extreme levels of aluminum found in the brains of the study’s teenage donors have alarming implications for the entire generation of highly aluminum-vaccinated children.

Given that it is no longer unheard of to see Alzheimer’s being diagnosed in people who are in their 20s, 30s, or 40s, it is not unreasonable to worry that a catastrophic new wave of AD may be about to compound children’s already heavy burden of ASD and other neurological disorders.

Recognizing the risks, numerous researchers have called for a halt to the use of aluminum salts in vaccines. The powerful results of this study underscore the urgency of heeding this plea as well as eliminating exposure to other sources of neurotoxic aluminum.